JP2011041157A - Method and apparatus for generating document image data, and computer program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a fault-free reading result of the image recorded on a plurality of sides of a sheet easier than the prior art. <P>SOLUTION: A document, where each page of a plurality of sheets is defined as an object of read operation, is set to the ADF. An image read control part 101 makes a scanner 10e read an image recorded on each page of the sheets sequentially fed from the ADF10j. A read fault detecting part 102 detects a defective page on which a fault is generated on the image among the pages that have been read by the scanner 10e. The image read control part 101 repeatedly reads the image on the defective page until the fault disappears. In addition, the image file generating part 105 generates an image file 6 of the document by merging image data 5 of the image of each page where any fault is not found. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method and apparatus for scanning a document.

  In recent years, image processing apparatuses called “multifunction machines” or “MFPs” that integrate functions such as copying, network printing (PC printing), faxing, and scanners are widely used in offices. It is gradually becoming popular in the home.

  In recent years, it has become common to read a document written on paper with a scanner and convert it into electronic data. Thereby, the space for storing documents can be reduced more than before.

  In addition, when multiple people exchange documents on paper, they are not copied to another paper and sent from one to the other, but the document is read by a scanner and converted into electronic data via a communication line. Sending data from one to the other has become common. As a result, transportation costs can be reduced more than before, and documents can be exchanged more quickly than before.

  An ADF (Auto Document Feeder) continuously carries out a plurality of sheets to a scanner. Therefore, if ADF is used, even an enormous number of documents written on a large number of sheets can be scanned and converted into electronic data without the operator having to set the sheets one by one. it can.

  By the way, when a plurality of sheets are continuously carried out to the scanner and scanning is performed, there is a case where an abnormality (defect) occurs in an image obtained from some sheets. Similarly, when both sides of one sheet are to be read, there may be an abnormality in the image on either side.

  The apparatus disclosed in Patent Document 1 performs scanning without stopping conveyance even if conveyance abnormality is detected during continuous scanning, and notifies the user of an abnormal image after scanning.

JP 2006-245953 A

  If an abnormality is detected, the operator may remove the cause of the abnormality and start scanning again from the beginning. Alternatively, only the paper in which the abnormality is detected may be scanned again, and the data in the portion where the abnormality is detected in the data obtained in the first scan may be replaced with the data obtained in the redo scan.

  However, according to the method of re-scanning from the beginning, the operator does not need to use his / her head very much, but it is not efficient because the paper which has not been detected abnormal is scanned again.

  On the other hand, according to the method of re-scanning and replacing data only for the paper in which an abnormality has been detected, the operator must extract the target paper from a bundle of multiple sheets and return it to the original position after scanning. . In addition, the image data must be updated using an application such as an image editor. Therefore, it takes time and effort for the operator. There is no denying the possibility of making mistakes.

  SUMMARY OF THE INVENTION In view of such problems, an object of the present invention is to make it possible to more easily obtain a reading result without abnormality of an image written on a plurality of surfaces of a sheet.

  According to an aspect of the present invention, there is provided a document image data conversion method for generating an image data of a document by reading an image written on a document having a plurality of reading surfaces that are target surfaces to be read, A first step that causes the image reading device to read a surface image that is an image written on the surface; and an abnormal surface that is a surface of the surface that is abnormal in the read surface image. A second step for causing the abnormality detection means to detect; a third step for causing the image reading device to repeatedly read the surface image until the abnormality is no longer detected; And a fourth step of generating the image data by merging the data of the surface images when the abnormality is not detected.

  Preferably, in the first step, the automatic document feeder sequentially conveys the surfaces to the image reading device, causes the image reading device to read the surface images of the surfaces, and In the step, the respective surfaces are sequentially conveyed to the image reading device by the automatic document conveying device, and only the surface image of the abnormal surface among the surfaces is read by the image reading device. The reading of the surface image is skipped.

Or a fifth step of causing the paper discharge transport mechanism to transport the document to the automatic document transport device after the surface image of each surface is read by the image reading device;
3. A method for converting document image data according to claim 2.

  Alternatively, in the third step, the condition is changed according to the abnormality of the abnormal surface, and the image reading device reads the surface image of the abnormal surface.

  According to the present invention, it is possible to more easily obtain a reading result of an image written on a plurality of surfaces of an original without abnormality.

It is a figure which shows the example of the whole structure of a network system. 2 is a diagram illustrating an example of a hardware configuration of an image forming apparatus. FIG. 2 is a diagram illustrating an example of a functional configuration of an image forming apparatus. FIG. It is a figure which shows the example of a page image state memory | storage part. It is a figure which shows the example of the kind of abnormality. 6 is a flowchart illustrating an example of the overall processing flow of the image forming apparatus. It is a figure for demonstrating the example of the procedure which produces | generates an image file. It is a figure for demonstrating the example of the procedure which produces | generates an image file.

  Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

  1 is a diagram illustrating an example of the overall configuration of the network system NS, FIG. 2 is a diagram illustrating an example of a hardware configuration of the image forming apparatus 1, and FIG. 3 is a diagram illustrating an example of a functional configuration of the image forming apparatus 1. It is.

  As shown in FIG. 1, the network system NS includes an image forming apparatus 1, one or a plurality of terminal apparatuses 2, a communication line 3, and the like. The image forming apparatus 1 and each terminal device 2 can be connected to each other via a communication line 3. As the communication line 3, a so-called LAN (Local Area Network) line, the Internet, a public line, a dedicated line, or the like is used.

  The network system NS is provided in a building of an organization such as a government office or a company, and is used by members of the organization (hereinafter referred to as “users”). In particular, according to the network system NS of the present embodiment, the user can convert the images written on a plurality of sheets into electronic data more easily than in the past while suppressing the occurrence of abnormalities (problems). Hereinafter, this mechanism will be described.

  The image forming apparatus 1 is an image processing apparatus generally called a multifunction peripheral or an MFP (Multi Function Peripherals), and integrates functions such as copying, PC printing (network printing), fax, scanner, box, and e-mail. Device.

  As shown in FIG. 2, the image forming apparatus 1 includes a CPU (Central Processing Unit) 10a, a RAM (Random Access Memory) 10b, a ROM (Read Only Memory) 10c, a mass storage device 10d, a scanner 10e, a printing device 10f, In addition to the network interface 10g, the touch panel 10h, the modem 10i, the ADF (Auto Document Feeder) 10j, and the paper discharge transport mechanism 10k, the control circuit is configured.

  The ADF 10j is a device that conveys the set sheets one by one to the scanner 10e. Generally, it may be called an “automatic document feeder”.

  The scanner 10e is an apparatus that generates image data by reading an image such as a photograph, a character, a picture, or a chart recorded on a sheet conveyed by the ADF 10j.

  The paper discharge transport mechanism 10k transports the paper processed by the scanner 10e to the ADF 10j.

  The printing device 10f prints an image read from a sheet by the scanner 10e or an image shown in image data received from another device.

  The touch panel 10h displays a screen for giving a message or an instruction to the user, a screen for the user to input processing commands and conditions, a screen showing the processing result of the CPU 10a, and the like. Moreover, the position which the user touched with the finger | toe is detected, and the signal which shows a detection result is transmitted to CPU10a.

  The network interface 10g is a NIC (Network Interface Card) for communicating with other devices such as the terminal device 2 via the communication line 3 using a protocol such as TCP / IP (Transmission Control Protocol / Internet Protocol).

  The modem 10i is a device for exchanging image data with other fax terminals using a protocol such as G3 via a fixed telephone network.

  The ROM 10c or the mass storage device 10d includes an image reading control unit 101, a reading abnormality detection unit 102, a feedback control unit 103, a scanning condition determination unit 104, an image file generation unit 105, an image file transmission unit 106, a page shown in FIG. A program for realizing the image state storage unit 121, the page image data storage unit 122, and the like is stored. These programs are loaded into the RAM 10b as necessary and executed by the CPU 10a. A hard disk or a flash memory is used as the large capacity storage device 10d.

  All or some of the functions of the units illustrated in FIG. 3 may be realized only by hardware such as a circuit.

  In addition to the driver of the image forming apparatus 1, the terminal device 2 is installed with an application for creating or editing an image. The user operates the terminal device 2 to prepare an image, and the image forming apparatus 1 can print the image. Further, the image forming apparatus 1 can be operated to scan and digitize the image written on the paper and transfer it to the terminal device 2.

  FIG. 4 is a diagram illustrating an example of the page image state storage unit 121, and FIG. 5 is a diagram illustrating an example of the type of abnormality.

  Next, regarding the processing contents of each part of the image forming apparatus 1 shown in FIG. 3, the document 7 composed of five sheets (see FIG. 7A) is scanned and the electronic data of the document 7 is transmitted to the terminal device 2. A case will be described as an example. It is assumed that the image as the content is written on only one side of each sheet. That is, the document surface (reading surface) is not a double-sided sheet but a single-sided sheet. Also, one page of content is written on one document surface. Therefore, hereinafter, the first, second,..., Fifth document surface is referred to as “first page”, “second page”,..., “Fifth page”.

  The user sets the document 7 on the ADF 10j and operates the touch panel 10h to give a scan command to the image forming apparatus 1. At this time, the transmission destination of the file obtained by scanning the document 7 is designated.

  In the image forming apparatus 1, when a scan command is received, the image reading control unit 101 in FIG. 3 controls the scanner 10 e so as to sequentially scan each page of the document 7. Further, the scanner 10e is controlled so as to redo the scan of the page detected by the reading abnormality detection unit 102 described later that the abnormality has occurred.

  As shown in FIG. 4, the page image state storage unit 121 stores page state information 4 for each page of the document 7 read by the scanner 10e.

  In the page status information 4 of a certain page, “page name” is an identifier of the page. Page names such as “first page”, “second page”,... Are given in the order read by the scanner 10e.

  The “abnormal flag” indicates whether an abnormality is detected from the page. “Abnormality type” indicates the type (type) of abnormality detected from the page. “Scanning condition” indicates a condition to be applied when scanning the page.

  Note that the initial value of the abnormality flag is not “off” which means that an abnormality has been detected, but is not “off” which means that no abnormality has been detected. For example, “NULL” is used. “NULL” is also used as the initial value of the abnormality type. As the initial value of the scanning condition, a reading condition (for example, a condition such as reading density or resolution) set as a default in the image forming apparatus 1 is used. Alternatively, conditions specified by the user before the start of scanning may be used.

  A process for generating the page state information 4 and a process for updating the page state information 4 will be sequentially described later.

  Returning to FIG. 4, the page image data storage unit 122 stores the image data 5 of the image of each page obtained by the scanner 10e. Note that a page in which an abnormality is detected by the reading abnormality detection unit 102 is scanned again. If no abnormality is detected from the image obtained by re-scanning, the existing (old) image data 5 of the page is deleted from the page image data storage unit 122, and instead of the image for which no abnormality has been detected. Image data 5 is newly stored in the page image data storage unit 122.

  The reading abnormality detection unit 102 checks the image of each page read by the scanner 10e, and detects the presence and type of abnormality. In the present embodiment, three types of blackout, drowning, and skew are detected as abnormal types.

  As shown in FIG. 5A, “blackout” means that a region of a predetermined area or more in the read page image is blackened out.

  “Turning” means that the entire read page turns whitish as shown in FIG. 5B.

  “Slanting” is a state in which a predetermined one side of the paper and a predetermined one side of the glass surface of the scanner 10e are read in an oblique state without forming the original angle, and an image as shown in FIG. 5C is obtained. It means to be.

  It can be detected by a known technique whether the image of the page read by the scanner 10e corresponds to a blacked-out image, a blurred image, or a skewed image. For example, a set of continuous pixels whose black density is equal to or higher than a predetermined value is searched, and if there are a predetermined number or more of pixels, it is detected that black crushing has occurred. Alternatively, if the white density of the entire page is equal to or less than a predetermined value, it is detected that a blur has occurred. Alternatively, a rectangular area is detected from the image on the page, and if the base of the rectangle is inclined at a predetermined angle or more with respect to the reference line segment, it is detected that skew has occurred. In addition, a method for detecting these abnormalities based on a histogram is also known.

  When an abnormality is detected from a certain page by the reading abnormality detection unit 102, the “abnormal flag” of the page status information 4 (see FIG. 4) of the page is updated to “on”, and the “abnormal type” is detected. Updated to anomaly type. On the other hand, if not detected, the “abnormal flag” is updated to “off”.

  Returning to FIG. 3, when the document 7 needs to be scanned again, that is, when an abnormality is detected by the reading abnormality detection unit 102, the feedback control unit 103 discharges the document 7 read by the scanner 10 e. The paper discharge transport mechanism 10k is controlled so as to be transported to 10k. That is, control is performed to feed back the document 7 to the paper discharge transport mechanism 10k.

  When an abnormality is detected by the reading abnormality detection unit 102, the scan condition determination unit 104 determines a condition for rescanning an abnormal page. For example, when black crushing is detected as an abnormality, the reading density condition when the page is scanned again is determined to be lower than the reading density when black crushing is detected by a predetermined value. Alternatively, when the blur is detected as an abnormality, the reading density condition when the page is scanned again is determined to be higher by a predetermined value than the reading density when the blur is detected.

  Then, the “scan condition” of the page state information 4 of the page is updated to the determined condition.

  The image file generation unit 105 merges (integrates) the image data 5 of each page of the document 7 when no abnormality is detected, and converts the image data 5 into a predetermined format (for example, PDF or TIFF). File 6 is generated.

  The image file transmission unit 106 transmits the image file 6 generated by the image file generation unit 105 to a transmission destination designated by the user.

  FIG. 6 is a flowchart for explaining an example of the overall processing flow of the image forming apparatus 1, and FIGS. 7 and 8 are diagrams for explaining an example of a procedure for generating the image file 6.

  Next, a scanning process procedure in the image forming apparatus 1 will be described with a specific example with reference to a flowchart of FIG.

  As shown in FIG. 7A, the user sets the document 7 with an image written on each page in the ADF 10j. Then, the touch panel 10h is operated to specify a transmission destination and input a scan command.

  Then, the image forming apparatus 1 executes processing in the following procedure. First, the image forming apparatus 1 performs initial setting (# 11 in FIG. 6). For example, the scan target is set for all pages of the document 7. However, before starting the scan, the number of pages is unknown. Therefore, according to this setting, as described below, the sheets of the document 7 are scanned one by one without being skipped. In addition, conditions such as reading density are set to default values. A value specified by the user may be set instead of the default value.

  The image forming apparatus 1 reads the image of the first page under the default condition, generates the image data 5 of the first page, and stores this (# 12). At this time, page state information 4 (see FIG. 5) for the first page is prepared.

  The image forming apparatus 1 checks whether the read image is normal (# 13). Specifically, it is checked whether or not any of the above types of abnormalities is applicable.

  If there is an abnormality (Yes in # 14), the image forming apparatus 1 updates the abnormality flag of the page state information 4 of the first page to “on”, and the abnormality type is detected as the type of abnormality detected (type). (# 15). Further, a rescan condition is determined according to the type of abnormality, and the scan condition is updated to the determined condition (# 16).

  On the other hand, if there is no abnormality (No in # 14), the image forming apparatus 1 updates the abnormality flag of the page state information 4 of the first page to “off” (# 17).

  If the current scan is a rescan and the abnormality flag is updated from on to off (Yes in # 18), the image forming apparatus 1 has stored the first page so far. The image data 5 is deleted, and the image data 5 obtained by the current scan is newly stored (# 19). That is, the replacement of the image data 5 is performed. However, in the first scan, there is no update from on to off.

  The image forming apparatus 1 executes the same process as that described above for the first page for the second and subsequent pages. As a result, it is assumed that an abnormality is detected from the first page and the fifth page as shown in FIG.

  When the image forming apparatus 1 detects an abnormality from any page of the document 7 (Yes in # 21), only the pages where the abnormality is detected (in this example, the first page and the fifth page) are changed to scan targets. While setting (# 22), the document 7 is returned to the ADF 10j (# 23). And about the page, the process of said # 12- # 19 is suitably performed. However, when scanning is performed, the scan condition indicated in the page state information 4 of the page is applied.

  Similarly, the image forming apparatus 1 scans a page in which an abnormality is detected until no abnormality is detected from any page.

  As a result of the rescanning, it is assumed that image data 5 of an image having no abnormality is generated for the first page and the fifth page as shown in FIG. Then, as shown in FIG. 8B, the image forming apparatus 1 deletes the previously generated image data 5 for each of the first page and the fifth page, and newly creates the image data 5 generated by the rescan. Store (Yes in # 18, # 19). That is, the replacement of the image data 5 is performed.

  When the image forming apparatus 1 does not detect any abnormality from any page (No in # 21), the image forming apparatus 1 generates the image file 6 by merging the image data 5 of each page (# 24), and is designated by the user. The image file 6 is transmitted to the transmitted destination (# 25).

  According to the present embodiment, it is possible to more easily obtain a reading result of an image written on a plurality of surfaces of an original without any abnormality.

  In this embodiment, the case where the image forming apparatus 1 includes the paper discharge transport mechanism 10k has been described as an example. However, when the paper discharge transport mechanism 10k is not included, the user reads the document 7 read by the scanner 10e. Hold it in your hand and return it to ADF10j.

  In this embodiment, the image forming apparatus 1 changes the reading density and performs reading again when black crushing or blurring occurs as an abnormality. Change and read again. For example, if the read image includes a text image representing text, but the OCR (Optical Character Reader) function cannot be applied to the text image, the resolution may be increased and reading may be performed again.

  If skewing occurs repeatedly on a specific page, the page may be broken. Therefore, when skew has occurred a predetermined number of times on a specific page, a message prompting to check that page may be displayed together with a message to that effect. If any other abnormality occurs, a message to that effect may be displayed.

  In the present embodiment, the case where only one side of one sheet is a document surface has been described as an example, but the present invention can also be applied to a case where both sides are document surfaces. In the latter case, an ADF corresponding to double-sided scanning is used as the ADF 10j, the first surface, the first back surface, the second surface, the second back surface,..., The Nth surface, N What is necessary is just to make the scanner 10e read in order of the back side of the sheet.

  In addition, the configuration of the entire network system NS and the image forming apparatus 1 or each unit, the processing content, the processing order, the configuration of the page status information 4 and the like can be appropriately changed in accordance with the spirit of the present invention.

1 Image forming device (document image data conversion device)
101 Image reading control unit (reading control means)
102 Reading abnormality detection unit (abnormality detection means)
105 Image file generator (image data generator)
10e Scanner (reading means)
6 Image file (image data)
7 Manuscript

Claims (6)

An original image data conversion method for generating an image data of an original by reading an image written on an original having a plurality of reading surfaces to be read.
A first step for causing the image reading device to read a surface image, which is an image written on the surface, for each surface;
A second step of causing the abnormality detection means to detect an abnormal surface that is a surface in which an abnormality has occurred in the read surface image of the surface;
A third step of causing the image reading device to repeatedly read the surface image until the abnormality is not detected; and
A fourth step of causing the image data generation means to generate the image data by merging the data of the surface images of the respective surfaces when the abnormality is not detected;
A document image data conversion method characterized by comprising: In the first step, the automatic document feeder sequentially conveys the surfaces to the image reading device, and causes the image reading device to read the surface images of the surfaces.
In the third step, the automatic document feeder sequentially conveys each surface to the image reading device, and causes the image reading device to read only the surface image of the abnormal surface of the surfaces, Skip reading of the surface image of other surfaces,
The document image data conversion method according to claim 1. A fifth step of causing the discharge conveyance mechanism to convey the document to the automatic document conveyance device after the surface image of each surface is read by the image reading device;
3. A method for converting document image data according to claim 2. In the third step, the condition is changed according to the abnormality of the abnormal surface and the surface image of the abnormal surface is read by the image reading device.
4. A document image data conversion method according to claim 1. A document image data conversion device that reads an image written on a document having a plurality of reading surfaces, which are target surfaces, and generates image data of the document,
Reading means for reading a surface image that is an image written on the surface for each surface;
An abnormality detection means for detecting an abnormal surface that is an abnormal surface in the read surface image among the surfaces;
A reading control means for causing the reading means to read the surface image until the abnormality is not detected for the abnormal surface;
Image data generating means for generating the image data by merging the data of the surface images when the abnormality is not detected for each surface;
A document image data conversion apparatus comprising: A computer program used in a document image data conversion apparatus that reads an image written on a document having a plurality of reading surfaces to be read and generates image data of the document,
In the document image data conversion device,
For each surface, a process of reading a surface image that is an image written on the surface;
A process of detecting an abnormal surface that is a surface where an abnormality has occurred in the read surface image of the surface;
A process of repeatedly reading the surface image until the abnormality is not detected;
A process of generating the image data by merging the data of the surface images when the abnormality is not detected for each surface;
A computer program for executing

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